KR102003364B1 - Collapsible steering column assembly - Google Patents

Abstract

A locking member can move closer to or away from a telescopic tooth member while moving linearly, and has a structure of being resiliently pressed towards the telescopic tooth member by means of a locking spring member in a locked state. Therefore, even if a thread of a telescopic tooth of the telescopic tooth member and a thread of a telescopic locking tooth of the locking member overlap and thus incomplete tooth engagement occurs, the telescopic tooth of the telescopic tooth member and the telescopic locking tooth of the locking member can be engaged immediately after tilting due to collision. Therefore, the present invention guarantees a stable energy absorbing function.

Description

[0001] Collapsible steering column assembly [0002]

The present invention relates to a collapsible steering column assembly that can be collapsed upon impact by applying an energy absorbing function.

The steering column assembly is connected to a steering wheel of the vehicle so as to perform steering by the operation of the driver. Typically, the steering column assembly is configured for tilt and telescopic behavior for the operator's convenience. The tilt behavior adjusts the angular position of the steering wheel, and the telescopic behavior adjusts the longitudinal position of the steering column. A locking unit is typically provided which selectively enables such tilting and telescopic behavior. When the lock unit is in the locked state, the tilt and telescopic behavior is interrupted to maintain the position of the steering wheel and tilt and telescopic behavior is allowed if the lock unit is in the unlocked state.

On the other hand, such a steering column assembly can be formed so as to collapse while absorbing energy in the event of an impact such as a vehicle collision. In other words, when the driver collides with the steering column, the inner jacket is introduced into the outer jacket by the impact force to collapse, and the impact energy is absorbed in the process. A steering column having such a function is usually called a collapsible steering column. Conventionally, in order to realize such an energy-absorbing function, a method of inserting a tolerance ring between an upper jacket and an outer jacket, a method of applying an energy absorbing strap, And methods of using collapse have been introduced.

According to the complicable steering column assembly disclosed in U.S. Patent No. 8,375,822, the energy absorbing strap connected to the upper jacket and the lock member connected to the outer jacket are selectively engaged with each other corresponding to the rotation of the lock lever constituting the lock unit Wherein the locking member and the energy absorbing strap are unlocked when the locking lever is in the unlocked state so that the upper jacket and the energy absorbing strap are capable of longitudinal telescopic movement relative to the outer jacket, The locking member and the energy absorbing strap are in a locked state to limit the telescopic behavior in the longitudinal direction of the upper jacket relative to the outer jacket. At this time, when an impact force is applied to the upper jacket due to a vehicle collision accident or the like in the locked state, the energy absorbing strap is deformed and the upper jacket collapses into the outer jacket. According to the structure of US Pat. No. 8,375,822, since the teeth are formed on the surface of the energy absorbing member in the form of a thin plate, the strength of the portion where the energy absorbing strap is engaged with the teeth of the lock member and the deformation of the energy absorbing strap There is a problem that there is a conflict between the securing of smooth deformation characteristics of the parts. Also, there is a problem in that the structure is complicated because a plurality of rotational force transmitting members are required to rotate the lock member.

US registered patent US 8,375,822 (registered on February 19, 2013) US registered patent US 8,403, 364 (registered on Mar. 26, 2013) US registered patent US 8,500,168 (registered on August 06, 2013) U.S. Pat. No. 5,562,307 (issued Oct. 08, 1999) British Published Patent GB2291840 (Published on July 02, 1996) European patent EP0772541 (registered on June 05, 1998) US Patent No. 5,595,399 (registered on January 21, 1997) US Patent 6,623,036 (registered on September 23, 2003) U.S. Published Patent Application No. 2006/0181070 (Published on August 17, 2006) U.S. Published Patent Application US2007 / 0138781 (Published on Jan. 21, 2007) U.S. Published Patent Application No. US2008 / 0023952 (Published on January 31, 2008) U.S. Published Patent Application No. US2016 / 0159387 (published on January 09, 2016)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a compliant steering column assembly having an energy absorbing structure that is simple in structure and can operate stably.

In particular, the present invention provides a collapsible steering column assembly capable of causing an energy-absorbing function to take place immediately after an impact even in the state of incomplete fitting of teeth for operation of the energy-absorbing structure.

A compliant steering column assembly according to an embodiment of the present invention includes a mounting bracket having a pair of arms facing each other, a lower housing installed between the pair of arms of the mounting bracket, a telescopic behavior And a top jacket installed to penetrate through the lower housing to allow the telescopic movement of the steering column to be selectively released by selectively applying a clamping force to the pair of arms so that the telescopic behavior of the steering column is locked or unlocked And a collision of the steering column caused by energy absorption when an impact is applied to the steering column in a locked state of the lock unit, Acting as permissive It includes an energy-absorbing structure. Wherein the energy absorbing structure comprises a telescopic tooth member having a telescopic tooth, a telescopic lock capable of selectively engaging the telescopic tooth, and an optional coupling of the telescopic lock tooth and the telescopic tooth corresponding to a locked or unlocked state of the lock unit A locking member operative to selectively block or permit movement of the telescopic tooth member in the telescopic movement direction through the telescopic tooth member, Wherein the telescopic member is operative to telescopically move with the upper jacket and to transmit the telescopic tooth member to the telescopic member when the movement of the member in the telescopic movement direction is blocked, And an energy absorbing member that acts to cause energy absorption while the shape is deformed by relative movement. Wherein the energy absorbing member is connected to the body portion and the telescopic tooth member, respectively, and the energy absorbing member is connected to the telescopic tooth member by a shape deformation caused by the relative movement of the upper jacket to the body member and the telescopic tooth member, And a shape deforming portion for generating the deformed portion.

The shape deforming portion may be a J-shaped strap connected to the body portion.

The shape deforming portion may be fastened to the telescopic tooth member by a fastening pin passing through the fastening portion provided at the end portion of the J-shaped strap.

The energy absorbing structure may further include a guide member fixed to the upper jacket and guiding the telescopic tooth member during relative movement of the upper jacket and the telescopic tooth member in the telescopic direction.

Shaped strap may be provided on both sides of the J-shaped strap so as to be broken in the shape deformation process.

The telescopic teeth may be arranged along the longitudinal direction of the upper jacket and the locking member is configured to make a linear movement in a direction of approaching or moving away from the telescopic tooth member in response to switching to a locked or unlocked state of the locking unit .

The lock unit may include a lever rotatable between a locked position and an unlocked position, and a tilt bolt configured to rotate with the lever to rotate between a locked position and an unlocked position. Wherein the energy absorbing structure comprises a cam member configured to pivot the locking member in a direction away from the telescopic tooth member in response to rotation of the tilt bolt to the unlocked position, a support member coupled to the lower housing, And a locking spring member elastically supporting the locking member with respect to the member in a direction approaching the telescopic tooth member.

The support member may be resiliently supported toward the lock member by a support spring member fastened to the mounting bracket.

The locking unit may include a lever capable of pivoting between a locked position and an unlocked position, and a tilt bolt rotating with the lever and penetrating a pair of arms of the mounting bracket. The telescopic tooth member may include a first portion defining the telescopic teeth, and a second portion spaced from the first portion and facing the outer surface of the upper jacket. The tilt bolt may be installed to pass through a space between the first portion and the second portion.

According to another aspect of the present invention, there is provided a collapsible steering column assembly including: a mounting bracket having a pair of arms facing each other; a lower housing installed so as to pass between a pair of arms of the mounting bracket; A steering column including an upper jacket installed to penetrate through the lower housing so as to allow the steering wheel to selectively move in a locked state or an unlocked state to selectively allow the telescopic behavior of the steering column by applying a clamping force to the pair of arms; And the steering column is operated in conjunction with the locked state or the unlocked state of the locking unit, and when the impact is applied to the steering column in the locked state of the locking unit, To be allowed It includes an energy-absorbing structure. Wherein the energy absorbing structure comprises a telescopic tooth member having a telescopic tooth, a telescopic lock that can be engaged with the telescopic tooth, and wherein the telescopic locking tooth and the telescopic tooth correspond to the locked or unlocked state of the locking unit, The lock member being configured to move between the unlock position and the unlock position, a cam member configured to move the lock member in a direction in which the telescopic lock and the telescopic tooth are disengaged from each other, A lock spring member elastically supporting the lock member in a direction in which the telescopic lock is engaged with the telescopic lock in response to the switching of the lock unit to the locked state, Wherein the telescopic tooth member is movable in conjunction with the upper jacket in the disengaged state of the teeth and the energy absorbing through the deformation by the impact applied to the steering column in the state of the telescopic locking teeth and the telescopic teeth are engaged, And an energy absorbing member functioning to allow collapse of the column.

The lock unit may include a lever capable of pivoting between a locked position and an unlocked position, and a tilt bolt configured to rotate with the lever to rotate between a locked position and an unlocked position, May be fastened to the tilt bolt to rotate together with the tilt bolt.

The energy absorbing structure may further include a support member supported by a support spring member fastened to the mounting bracket, and the lock spring member may elastically support the lock member with respect to the support member.

According to another aspect of the present invention, there is provided a collapsible steering column assembly including: a mounting bracket having a pair of arms facing each other; a lower housing installed so as to pass between a pair of arms of the mounting bracket; A steering column including an upper jacket installed to penetrate through the lower housing so as to allow the steering wheel to selectively move in a locked state or an unlocked state to selectively allow the telescopic behavior of the steering column by applying a clamping force to the pair of arms; And the steering column is operated in conjunction with the locked state or the unlocked state of the locking unit, and when the impact is applied to the steering column in the locked state of the locking unit, To be allowed It includes an energy-absorbing structure. Wherein the energy absorbing structure comprises a telescopic tooth member having a telescopic tooth, a telescopic lock that can be engaged with the telescopic tooth, and wherein the telescopic locking tooth and the telescopic tooth correspond to the locked or unlocked state of the locking unit, The lock member being configured to move between the unlock position and the unlock position, a cam member configured to move the lock member in a direction in which the telescopic lock and the telescopic tooth are disengaged from each other, A lock spring member elastically supporting the lock member in a direction in which the telescopic lock is engaged with the telescopic lock in response to switching of the lock unit to the locked state, It includes an energy absorption member connecting. The telescopic teeth are arranged along the telescopic direction of the upper jacket and the locking member is configured to be movable between a mating and unmating position of the telescopic pin and the telescopic pin through a linear movement of the telescopic tooth member. Wherein the energy absorbing member functions to move the telescopic tooth member together with the upper jacket in a disengaged state between the telescopic lock tooth and the telescopic tooth and to apply an impact applied to the steering column in the meshed state between the telescopic lock tooth and the telescopic tooth So as to allow the collapse of the steering column while allowing energy absorption through the shape deformation.

Wherein the energy absorbing member is connected to the body portion and the telescopic tooth member, respectively, and the energy absorbing member is connected to the telescopic tooth member by a shape deformation caused by the relative movement of the upper jacket to the body member and the telescopic tooth member, And a shape deforming portion to be formed.

The lock unit may include a lever capable of pivoting between a locked position and an unlocked position, and a tilt bolt configured to rotate with the lever to rotate between a locked position and an unlocked position, May be fastened to the tilt bolt to rotate together with the tilt bolt.

The energy absorbing structure may further include a support member supported by a support spring member fastened to the mounting bracket, and the lock spring member may elastically support the lock member with respect to the support member.

According to the present invention, an energy absorbing structure can be generated at the time of collapse of the steering column corresponding to the locked state of the lock unit by a simple structure by the telescopic member, the energy absorbing member, and the lock member. In particular, since the locking member is configured to move in a direction approaching or departing from the telescopic tooth member while linearly moving, and has a structure for resiliently urging the locking member toward the telescopic tooth member through the locking spring member in the locking state, Even if incomplete tooth coupling occurs due to the overlapping of the telescopic pin of the member with the telescopic lock of the lock member, the telescopic pin of the telescopic pin member and the telescopic lock of the lock member may be engaged immediately after the tilt due to the collision. This ensures a stable energy-absorbing function.

1 is a perspective view of a collapsible steerable column assembly according to an embodiment of the present invention.
2 is a bottom perspective view of a collapsible steering column assembly according to an embodiment of the present invention.
3 is an exploded perspective view of a collapsible steering column assembly according to an embodiment of the present invention.
4 is a perspective view showing a locking unit of a collapsible steering column assembly according to an embodiment of the present invention.
5 is an exploded perspective view of an auxiliary locking structure of a collapsible steering column assembly according to an embodiment of the present invention.
Figure 6 is a side view of the locking unit of Figure 4;
7 is a cross-sectional view taken along the line VII-VII in FIG.
8 is a cross-sectional view taken along line VIII-VIII of FIG.
9 is a cross-sectional view taken along line IX-IX of Fig.
10 is a cross-sectional perspective view taken along line IX-IX of Fig.
11 is a schematic perspective view of an energy-absorbing structure of a collapsible steering column assembly according to an embodiment of the present invention.
12 is a cross-sectional view taken along the line II-II in Fig.
13 is a cross-sectional view taken along the line III-III in Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, the collapsible steering column assembly includes a steering column 10, a lower housing 22, and a mounting bracket 20.

The steering column 10 includes an upper jacket 11 and an upper steering shaft 13 disposed in the upper jacket 11. [ The upper steering shaft 13 may be connected to a steering wheel (not shown) of the vehicle and configured to rotate with the steering wheel. Although not shown in the drawing, the steering column 10 may include a lower steering shaft that is coupled to the upper steering shaft 13 so as to be relatively movable in the longitudinal direction. For example, the lower steering shaft may be connected to the intermediate shaft via a universal joint. 1, the steering column 10 is movable in the telescopic direction 15 and can be tiltably mounted in the tilt direction 16, for example.

3, bearings 131 and 132 for supporting the upper steering shaft 13 of the steering column 10 may be provided, and the sleeve member 133 to which the upper steering shaft 13 is inserted, A retaining ring 134, and the like.

The mounting bracket 20 may be fixed to the vehicle body and may include a pair of arms 201 and 202 facing each other. As shown in Fig. 3, the pair of arms 201 and 202 facing each other are formed so that the upper jacket 11 passes through them. The arms 201 and 202 can be formed to be elastically deformable in a direction in which they approach each other when an external force (clamping force) is applied.

The lower housing 22 is installed so as to pass between the pair of arms 201, 202 of the mounting bracket 20. When the tilting function of the steering column 10 is provided, the lower housing 22 can be tilted relative to the mounting bracket 20. The steering column 10 can be tilted together with the lower housing 22 during tilting.

10, the lower housing 22 can form a cylinder-shaped receiving space 25 extending in the longitudinal direction, and the steering column 10, specifically, The jacket 11 is slidably installed. The telescopic behavior of the steering column 10 is caused by the sliding of the steering column 10 in the lower housing 22 and the tilting behavior of the steering column 10 due to the tilting of the steering column 10 with the lower housing 22 It happens. That is, the steering column 10 is inserted into the lower housing 22 so as to enable the telescopic behavior through the relative movement with respect to the lower housing 22 and the tilt behavior that occurs together with the lower housing 22.

3, the lower housing 22 may include a pair of legs 23 to face a pair of arms 201, 202 of the mounting bracket 20. As shown in FIG. 3 and 5, a pair of legs 23 of the lower housing 22 are spaced apart from each other by a predetermined distance in a state of being in contact with the inner surfaces of the pair of arms 201, 202 of the mounting bracket 20 Respectively. As shown in FIG. 3, the lower housing 23 is formed into a hollow cylindrical shape in which a part of the lower housing 23 is removed, and the pair of legs 23 may be broken by this structure.

Meanwhile, during the tilting operation, the lower housing 22 and the support spring member 24 for preventing the steering column 10 supported by the lower housing 22 from falling down may be provided. The supporting spring member 24 may be a spring having elastic restoring force and both ends 241 are fastened to the pair of arms 201 and 202 of the mounting bracket 20 respectively and the supporting portion 242, So that the combined body of the housing 22 and the steering column 10 can be elastically supported.

One end of the upper jacket 11 is movably inserted into the lower housing 22 along the longitudinal direction (i.e., telescopic direction). When an impact force capable of causing collapse in the telescopic locking state is applied to the steering column 10, the upper jacket 11 is pushed into the lower housing 22 to collapse, and energy absorption takes place in this process. This will be explained later.

1 and 2, the upper jacket 11 is inserted between the legs 23 of the housing 22 in a partially inserted state in the lower housing 22, and between a pair of arms 23 of the mounting bracket 20, (201, 202).

The collapsible steering column assembly according to an embodiment of the present invention includes a locking device 30 that operates to selectively lock or allow telescopic behavior. At this time, if the tilt behavior is provided, the tilt behavior can be selectively locked or allowed by the lock unit 30. [ Hereinafter, the case where both telescopic and tilt functions are provided will be described.

The lock unit 30 can be selectively placed in the locked state and the unlocked state, and the telescopic and tilt behavior is blocked in the locked state, and the telescopic and tilt behavior is permitted in the unlocked state. On the other hand, when an impact is applied to the steering column 10 in the locked state of the lock unit 30, the steering column 10 can be collapsed.

The locking unit 30 is configured to selectively apply a clamping force to the pair of arms 201 and 202 of the mounting bracket 20 so that the telescopic and tilting behavior of the steering column 10 is selectively enabled . When a clamping force is applied to the pair of arms 201 and 202 of the mounting bracket 20, a pair of arms 201 and 202 of the mounting bracket 20 and a pair of legs 23 are brought close to each other by the clamping force so that the friction between the pair of arms 201, 202 of the mounting bracket 20 and the pair of legs 23 of the lower housing 22 The friction between the pair of legs 23 of the lower housing 22 and the upper jacket 11 increases to block the tilt movement and the telescopic movement.

The lock unit 30 may include a lever 31 capable of pivoting between a locked position and an unlocked position and a tilt bolt 32 fastened to the lever 31 to rotate therewith . The tilting bolt 32 is formed by a pair of arms 201 and 202 of the mounting bracket 20 and a pair of lower housings 22 Can be installed through the legs (23). The tilt bolt 32 defines a longitudinal axis transverse to a pair of arms 201,202 of the mounting bracket 20 and a pair of legs 23 of the lower housing 22, And is rotatably installed. Further, the tilt bolt 32 is tilted together with the steering column 10 when the steering column 10 tilts. At this time, both side ends of the tilt bolt 32 are respectively protruded to the outside of the pair of arms 201 and 202 of the mounting bracket 20. The lever 31 is connected to one end and the thread 321 The fixing nut 33 can be fastened. Under such a structure, the rotation of the lever 31 enables the tilt bolt 32 to rotate about its longitudinal axis.

Specifically, through holes 211 and 212 are formed in the pair of arms 201 and 202 of the mounting bracket 20, respectively, and through-holes 211 and 212 are formed in corresponding positions of the pair of legs 23 of the lower housing 22 Holes 231 are formed. The tilt bolt 32 is provided so as to pass through these through holes 211, 212, and 231. The through holes 211 and 212 of the mounting bracket 20 may have a shape of a long hole extending in the tilt direction as shown in FIG. 3 so that the tilt bolt 32 can be rotated when the tilt is performed .

Hereinafter, the locking unit according to the embodiment of the present invention will be described in detail with reference to FIG. 3 to FIG.

3 and 7, the lock unit 30 may include a first cam member 34 and a second cam member 35 which are cam-engaged with each other. For example, the first cam member 34 may be integrally formed with the base portion 311 of the lever 31, and the second cam member 35 may be integrally formed with the first cam member 34 Can be interposed between the first cam member (34) and the arm (201) of the mounting bracket (20). The tilt bolt 32 and the first cam member 34 rotate together with the base portion 311 when the lever 31 rotates. At this time, the tilt bolt 32 is installed to penetrate the first and second cam members 34 and 35.

The first cam member 34 and the second cam member 35 may each have a cam surface in contact with each other, and the first cam member 34 is rotated by the cam surface structure, 35 in the longitudinal direction of the tilt bolt 32 while being pressed. At this time, the second cam member 35 is slightly pushed toward the arm 201 of the mounting bracket 20. 7, when the lever 31 is rotated in the locking direction, the first cam member 34 and the tilt bolt 32 rotate together with the lever 31 and are rotated by the rotation of the first cam member 34 The second cam member 35 is pushed by the first cam member 34 to be pushed toward the arm 201 of the mounting bracket 20. As a result, the arms 201 and 202 of the mounting bracket 20 and the legs 23 of the lower housing 22 are pressed by the clamping force of the second cam member 35 to be pushed inwardly, The legs 23 and the upper jacket 11 of the frame 22 may be pressed in order to block the telescopic behavior and the tilt behavior. That is, in the locked state, the pair of arms 201, 202 of the mounting bracket 20 are inwardly pushed by the clamping force to press the pair of legs 23 of the lower housing 22 and the lower housing 22 The inner surface of the lower housing 22 is pressed against the outer surface of the upper jacket 11 so that the movement of the upper jacket 11 in the lower housing 22 The telescopic behavior of the steering column 10 is cut off and the tilting behavior of the lower housing 22 is interrupted to block the tilting behavior of the steering column 10. [

On the other hand, an auxiliary lock structure 40 for supplementing the tilt lock function in the locked state of the lock unit 30 is applied. The auxiliary locking structure 40 is configured to operate in response to the rotation for locking and unlocking the tilt bolt 32 and serves to additionally block the tilt behavior when the tilt bolt 32 is in the locked state. As described above, the rotation of the lever 31 to the locked state causes the second cam member 35 to slightly move leftward in FIG. 7 to push the arm 201 of the mounting bracket 20, The first cam member 34 that applies a force to the second cam member 35 and the tilt bolt 32 fixed thereto are pushed along the axial direction to the right in Fig. 7 by the cam surface structure. The auxiliary locking structure 40 serves to compensate for the tilt lock function on the opposite side of the tilt bolt 32 by utilizing the axial movement of the tilt bolt 32. [

4 to 7, the auxiliary locking structure 40 is supported by the arm 202 of the mounting bracket 20 farther from the lever 31 and the thread 321 of the end of the tilt bolt 32 And is fixed between the fixing nuts 33.

5, the auxiliary locking structure 40 includes a support block 41, a lock spring member 42, a lock tooth member 43, an unlocking spring member 44, and a fixing tooth 48 . A bearing 45 can be interposed between the support block 41 and the fixing nut 33 and smooth rotation of the tilt bolt 32 with respect to the support block 41 can be achieved by the bearing 45. [ A guide member 47 for guiding the tilt bolt 32 so as to rotate in the tilt direction within the elongated hole 212 of the arm 202 and an impact absorbing member 46 for preventing impact during tilting, May be provided. Through holes are formed in these members 41, 42, 43, 44, 45, 47, and 46, and the tilt bolts 32 are installed through these through holes.

The locking teeth member 43 has movable locking teeth 431 provided on both sides thereof and the fixing teeth 48 which can be fastened to the moving locking teeth 431 are fixed to the arm 202 of the mounting bracket 20, As shown in FIG. 3 and 5, the movable locking teeth 431 and the fixed teeth 48 may extend along a direction parallel to the tilting direction of the tilt bolt 32. As shown in Fig. At this time, the fixed teeth 48 and the movable lock teeth 431 may be provided on both sides of the slot 212 of the arm 202, respectively. The auxiliary locking structure 40 is configured to perform the auxiliary locking function by engaging the movable locking teeth 431 and the fixed teeth 48. [

The support block 41 is supported via bearings 45 to a fixing nut 33 fastened to the tilt bolt 32. When the tilt bolt 32 is rotated to the locked position and the lever 31 is moved to the position where the lever 31 is located by the action of the cam members 34 and 35, the support block 41 is moved to the movement of the tilt bolt 32 And is pushed toward the arm 202 of the mounting bracket 20 correspondingly. The support block 41 may include a body portion 411 and four legs 412.

The locking spring member 42 may be a coil spring as shown in the figure and the locking spring member 42 is fixed to the supporting block 41 in the locking direction, And is elastically supported in a direction toward the surface 213. The lock spring member 42 can be installed so as to be in contact with the support block 41 and the lock tooth member 43 in a compressed state and resiliently supports the lock tooth member 43 by its elastic restoring force.

The locking member 43 may have a plate-like body portion 432 and the movable locking member 431 may be provided on both sides of the body portion 432. The lock spring member 42 can be supported on the surface of the body portion 432 of the lock tooth member 43.

The unlocking spring member 44 resiliently supports the lock tooth member 43 in the unlocking direction with respect to the support surface 213 of the arm 202, that is, in the direction away from the support surface 213 of the arm 202 do. The unlocking spring member 44 has a body portion 441 which contacts the lock tooth member 43 and supports the lock tooth member 43 and a supporting surface 213 of the arm 202 in the body portion 441 And may include a plurality of elastic legs 442 projecting toward the opposite side. The elastic legs 442 may be provided in four and supported on the support surface 213 of the arm 202. On the other hand, the unlocking spring member 44 may have a pair of holding arms 443 for holding the support member 41. [ The holding arm 443 may protrude from the body portion 441 toward the support block 41 and the retaining portion 444 provided at the end of the holding arm 443 may be inserted into the retaining block 44 413, respectively. The holding arm 443 is fastened to the support block 41 so that the support block 41, the lock spring member 42, the lock tooth member 43 and the unlocking spring member 44 are held in one unit .

When the tilt bolt 32 is rotated in the locked state, the support block 41 is moved toward the arm 202 so that the lock spring plate 42 is compressed, The elastic leg 442 of the unlocking spring member 44 is crushed and the body portion 441 of the unlocking spring member 44 is pushed toward the support surface 213 of the arm 202, (213). On the other hand, when the tilt bolt 32 is rotated from the locked state to the unlocked state, the support block 41 is moved in the direction away from the arm 202, whereby the resilient legs 442 The lock tooth member 43 is pushed in the direction away from the support surface 213 of the arm 202. As a result, The modulus of elasticity of the locking spring member 42 and the unlocking spring member 44 can be appropriately adjusted to enable such operation.

The fixing teeth 213 provided on the supporting surface 213 of the arm 202 can be selectively engaged with the moving lock teeth 431 of the lock tooth member 43 corresponding to the movement of the lock tooth member 43 Is placed at a certain position. 8A shows a locked state of the auxiliary locking structure 40 in accordance with the locked state of the tilt bolt 32, that is, the movable locking teeth 431 of the locking tooth member 43 are engaged with the fixed teeth 213 8B shows the unlocked state of the auxiliary locking structure 40 in accordance with the unlocked state of the tilt bolt 32, that is, the moving lock value 431 of the lock tooth member 43 And is not engaged with the fixed teeth 213. As shown in Fig. On the other hand, even when the lock tooth member 43 is moved toward the support surface 213 of the arm 202 by the rotation of the tilt bolt 32 into the locked state, the movement lock teeth 43 The movable lock teeth 431 of the lock tooth member 43 are not engaged with the fixed teeth 213 and the lock teeth 431 of the lock teeth 43 are not engaged with the fixed teeth 213. As a result, The movable lock teeth 431 of the member 43 are raised on the fixed teeth 213. Since the lock spring member 42 resiliently holds the lock tooth member 43 in this state even in this state, a slight rotation of the tilt bolt 43 due to the external force tilt action The movement of the lock tooth member 43 causes the movement of the lock tooth 431 of the lock tooth member 43 to come into contact with the point of the tooth of the fixed tooth 213. In this case, The lock tooth member 43 is moved toward the support surface 213 of the arm 202 by the restoring force to be in the locked state as shown in Fig. 8 (a). Thereby, the movable lock teeth 431 and the fixed teeth 213 of the lock tooth member 43 are engaged with each other, so that the additional tilt movement is interrupted.

The guide member 47 guides the tilt bolt 32 to move along a predetermined trajectory in the elongated hole 212 of the arm 202 when the tilt bolt 32 performs a tilt motion. For example, the guide member 47 may have guide protrusions 471 protruding from both sides thereof. When the guide protrusions 471 move in contact with the side surfaces 214 of the elongated holes 212, The tilting behavior of the guide member 32 can be guided. The shock absorbing member 46 is formed so as to absorb an impact due to collision with the upper surface and the lower surface 215 of the elongated hole 212 in the tilting motion of the tilt bolt 32. For this purpose, And a shock absorbing portion 461 at a portion facing the lower surface 215.

On the other hand, an energy absorbing structure 70 may be provided to cause energy absorption in the collapse of the steering column 10 in conjunction with the locking or unlocking operation of the locking unit 30. [ Hereinafter, the energy absorbing structure will be described with reference to Figs. 3 and 9 to 13. Fig.

The energy absorbing structure 70 functions to further block the telescopic behavior of the upper jacket 11 when the lock unit 30 is in the locked state and to absorb energy in response to the applied impact force, It acts so that collapse can occur. On the other hand, the energy absorbing structure 70 serves to allow the telescopic behavior of the upper jacket 11 when the lock unit 30 is in the unlocked state. For this function, the energy absorbing structure 70 includes a telescopic tooth member 71, a locking member 73, and an energy absorbing member 75.

The locking member 73 operates to selectively block or allow movement of the telescopic tooth member 71 in the telescopic direction of the locking unit 30 in response to the locked or unlocked condition.

The energy absorbing member 75 functions to cause the telescopic tooth member 71 to telescopic with the upper jacket 11 in a state in which the movement of the telescopic tooth member 71 in the telescopic direction is permitted, 71 is deformed by the relative movement of the upper jacket 11 in the direction of telescopic movement with respect to the telescopic tooth member 71 at the time of impact transmission in the state where the movement in the telescopic movement direction is blocked, energy absorption occurs Lt; / RTI >

3, 9 to 13, the telescopic tooth member 71 may have a plate shape arranged in contact with the outer surface of the upper jacket 11, and the telescopic tooth 711 may have a telescopic tooth May be provided on the outer surface of the member (71). The telescopic tooth member 71 is formed so that a selective locking with the locking member 73 can be made via the telescopic teeth 711, which will be described later.

The telescopic tooth member 71 is connected to the upper jacket 11 via an energy absorbing member 75 and is movable in the telescopic direction with the upper jacket 11 or in the telescopic direction with respect to the upper jacket 11 upon impact. Relative movement is possible. Specifically, when the telescopic tooth member 71 is in the unlocked state with the lock member 73, the telescopic tooth member 71 is brought into contact with the upper jacket 11 in the telescopic direction (I.e., telescopic behavior). On the other hand, when the telescopic tooth member 71 is in the locked state with the lock member 73, the telescopic tooth member 71 does not move with the upper jacket 11, And when a force in the telescopic direction is applied to the upper jacket 11 by an external impact in this state, the upper jacket 11 makes a relative movement with respect to the telescopic tooth member 71 at which the upper jacket 11 stops, 10), and in this process, energy absorption occurs due to deformation of the energy absorbing member 75.

The telescopic tooth member 71 includes a first extending portion 721 extending along the longitudinal direction of the upper jacket 11 and coming into close contact with the surface of the upper jacket 11, A second extending portion 722 extending along the longitudinal direction of the jacket 11 and first and second connecting portions 723 and 724 connecting both ends of the first and second extending portions 721 and 722, . ≪ / RTI > 11, the tilt bolt 32 is installed so as to pass through the space between the first extending portion 721 and the second extending portion 722. As shown in FIG. At this time, as shown in the figure, the telescopic teeth 711 are formed on the outer surface of the second extension part 722 and are arranged along a direction parallel to the longitudinal direction of the upper jacket 11.

A guide member 725 for guiding the telescopic tooth member 71 is fixed to the upper jacket 11. The guide member 725 guides one side end of the telescopic tooth member 71 and guides the movement in the telescopic direction when the telescopic tooth member 71 and the upper jacket 11 move relative to each other. For example, the guide member 725 may be formed to support both sides of the first extension portion 721 of the telescopic tooth member 71 so that the telescopic tooth member 71 Is guided by the guide member 725, the upper jacket 11 is moved relative to the telescopic tooth member 71. For example, the guide member 725 may be fixedly inserted into a groove formed in the upper jacket 11.

And a shock absorbing member 726 is provided on the telescopic tooth member 71. The shock absorbing member 726 may be formed of a material capable of absorbing impact such as rubber and may be installed at a position where the shock absorbing member 726 may collide with the tilt bolt 32 during the telescopic action.

The locking member 73 has a telescopic locking member 731 which can be selectively engaged with the telescopic member 711 of the telescopic tooth member 71. 13, the locking member 73 is disposed such that the telescopic locking member 731 faces the telescopic member 711 of the telescopic tooth member 71. The locking member 73 is configured to move linearly in the direction toward or away from the telescopic tooth member 71 in response to the rotation of the tilt bolt 32 for locking and unlocking the locking unit 30. [

9 to 13 show a state in which the telescopic teeth 711 and the telescopic locking teeth 731 are engaged with each other. In this state, in the direction in which the locking member 73 is moved away from the telescopic tooth member 71 11), the coupling between the telescopic pin 711 and the telescopic locking pin 731 is released. In other words, the locking member 73 is configured to be movable between the meshing position of the telescopic teeth 711 and the telescopic locking teeth 731 and the disengagement position.

The linear movement of the lock member 73 corresponding to the rotation of the tilt bolt 32 can be performed by the cam member 76. [ A pair of cam members 76 are fastened to the tilt bolt 32 so as to rotate together with the tilt bolt 32. For example, a pair of cam members 76 can be rotated together with the tilt bolt 32 by being fastened to the flat fastening portions 322 formed on the tilt bolt 32, respectively. At this time, the sleeve member 761 may be disposed between the cam member 76 and the tilt bolt 32. When the protruding portion of the cam member 75 comes into contact with the contact surface of the lock member 73 and rotates, a linear movement of the lock member 73 occurs.

On the other hand, a lock spring member 77 for elastically pressing the lock member 73 toward the telescopic tooth plate 71 is provided. The lock spring member 77 may be a coil spring and may be installed to elastically press the lock member 73 against the support member 78. [ The locking member 73 may have a seating groove 732 for seating the locking spring member 77. 3, the support member 78 includes a fastening leg 781 that can be folded and rested in a clip shape and the fastening leg 781 of the support member 78 is connected to the lower housing 22, The support member 78 can be fixed by being inserted into the fastening groove 232 formed in the leg 23 of the fastening member. On the other hand, as shown in FIG. 2, the support member 78 can be elastically pressed by the support portion 242 of the support spring member 24.

According to the embodiment of the present invention, since the lock spring member 77 maintains the state in which the lock member 73 is pressed toward the telescopic tooth member 71 in the locked state, the telescopic lock member 731 are placed on the mountain portion of the telescopic tooth 711 so that even when the telescopic locking teeth 731 and the telescopic teeth 711 are not completely engaged with each other, The telescopic locking pin 731 and the telescopic locking pin 711 are completely engaged by the restoring force. As a result, a force can be applied to the energy absorbing member 75 in the event of a collision, thereby enabling stable energy absorption and collapse of the steering column.

The energy absorbing member 75 allows energy absorption to occur at the collapse of the steering column. The energy absorbing member 75 is fixed on the one hand to the upper jacket 11 and on the other hand to the telescopic tooth member 71. The energy absorbing member 75 according to the embodiment of the present invention has a portion fixed to the upper jacket 11 and a portion where energy absorption takes place separately. That is, the energy absorbing member 75 includes a body portion 751 fixed to the upper jacket 11 and a deformed portion 753 fastened to the telescopic tooth member 71 to cause energy absorption by shape deformation .

3, 10, 11, and so on, the body portion 751 includes a pair of side plates 7511 spaced apart from each other in the width direction of the upper jacket 11, As shown in FIG. The side plate 7511 can be fixed to the surface of the upper jacket 11 by welding or the like and the deformed portion 753 can be connected to the transverse portion 7512. 10 and 13, the deformed portion 753 may be a J-shaped strap connected to the transverse portion 7512 of the body portion 751. At this time, fracture lines 754 for deformation of the deformed portion 753 are formed on both sides of the deformed portion 753 when the impact is transmitted. The broken line 754 may be made of a recess having a reduced thickness.

10, one end of the deformed portion 753 is connected to the transverse portion 7512 of the body portion 751, and the other end thereof is provided with the fastening portion 7531. The pair of fastening portions 7531 may be provided on both sides of the end portion of the deformed portion 753 and the pair of fastening portions 7531 may be respectively disposed on both sides of the telescopic tooth member 71 . The first connection portion 723 of the telescopic tooth member 71 is inserted between the pair of connection portions 7531 and the through hole 727 formed in the first connection portion 723 and the connection portion 7531 formed in the connection portion 7531 The fastening pin 74 is inserted into the through hole 7532. Whereby the shape deforming portion 753 and the telescopic tooth member 71 are connected.

On the other hand, a rigid reinforcing member 79 for reinforcing the rigidity in the rotating direction when the energy absorbing member 75 acts as a torque load in the rotating direction for the anti-theft function can be provided. The rigidity reinforcing member 79 may be fixed to the surface of the upper jacket 11 and the body portion 751 of the energy absorbing member 75 by welding, respectively.

This structure makes it possible to absorb the energy at the time of collapse of the steering column due to telescopic behavior and impact. The cam member 76 rotates together with the tilt bolt 32 to push the locking member 73 in the direction away from the telescopic tooth member 71 when the lever 31 is pivoted to the unlocking position, The telescopic locking member 731 of the lock member 73 and the telescopic member 711 of the telescopic tooth member 71 are disengaged from each other by the movement of the telescopic locking member 73. [ Further, since the clamping force by the lock unit 30 is released in this state, the telescopic behavior of the upper jacket 11 becomes possible. At this time, since the telescopic tooth member 71 is connected to the upper jacket 11 through the energy absorbing member 75, the telescopic tooth member 71 is moved together with the upper jacket 11.

On the other hand, when the lever 31 is pivoted to the locked position, the cam member 76 rotates together with the tilt bolt 32 so that the locking member 73 is elastically biased by the elastic restoring force of the locking spring member 77 71 of the telescopic tooth member 71 and the telescopic locking teeth 731 of the locking member 73 and the telescopic teeth 711 of the telescopic tooth member 71 are engaged by the movement of the locking member 73. Further, since the clamping force by the lock unit 30 is applied in this state, the telescopic behavior of the upper jacket 11 is interrupted. However, in this locked state, if the impact force is applied to the steering column 10 by a certain amount or more, collapse of the steering column 10 is achieved. That is, when the upper jacket 11 of the steering column 10 is pushed by the arm 21 of the mounting bracket 20 and the legs 23 of the lower housing 22, 11 collapse in the lower housing 22. At this time, since the telescopic tooth member 71 is fixed to the lock member 73 by tooth engagement and is connected to the upper jacket 11 through the energy absorbing member 75, The shape deformation of the shape deforming portion 753 of the energy absorbing member 75 and the energy absorption are carried out, and the collapse of the upper jacket 11 occurs. 11 and 13, when the upper jacket 11 is collapsed (moved in the X-axis direction in FIG. 11) in a state where the telescopic tooth member 71 is stopped, the body of the energy absorbing member 75 The portion 751 moves together with the upper jacket 11 and thereby breaks the broken line 754 on both sides of the deformed portion 753 and is transformed into a state shown in the dotted circle in Fig. In this way, the impact energy is absorbed and the collapse of the steering column is achieved.

Meanwhile, as described above, the pair of legs 23 of the lower housing 22 are configured to be folded in response to the rotation of the lever 31. 3, the lower housing 22 has a partition slot 233 for partitioning the legs 23 so that the legs 23 can be opened more easily. As a result, the portion located outside the partition slot 233 can be closed by the clamping force of the lock unit 30. In the case where the partition slots 233 are formed, when the force acts on the lower housing 22 due to the deformation force of the energy absorbing member 75 due to an external impact, Bending may occur. In the present invention, to intercept this bending phenomenon, a fitting member 83 for filling the partition slots 233 is provided. The bottom member 83 may include a pair of insertion portions 831 and a connecting portion 832 that are respectively inserted into the partition slots 233 formed in the pair of legs 23 of the lower housing 22 have. By providing the fitting member 83 for filling the partition slots 233, bending due to external force can be prevented, and the natural frequency characteristics of the entire system can be improved.

And a fixing member 84 for preventing the separating member 83 from coming off can be provided. The fixing member 84 may have the form of a plate and may be fixed to the lower housing 22 by a bolt 841 fastened to a screw hole 234 formed in the lower housing 22. The fixing member 84 may have a separation preventing portion 843 for pressing the fitting member 83. The separation preventing portion 843 may be formed by pressing the engagement protrusion 833 provided on the fitting member 83, The separation of the member 83 can be prevented. At this time, a shock absorbing bumper 85 may be interposed between the fixing member 84 and the lower housing 22. The shock absorbing bumper 85 has a shock absorbing function in the operation in the telescopic out direction.

On the other hand, an elastic member 86 for restoration of the leg 23 of the lower housing 22 partitioned by the partition slots 233 may be provided. The elastic member 86 is inserted into the mounting hole 235 formed in the leg 23 of the lower housing 22. The elastic member 86 may be formed of a curved line spring having an elastic restoring force, As shown in FIG.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

10: Steering column
11: upper jacket
20: Mounting bracket
201, 202: arm,
22: Lower housing
23: leg
24: Supporting spring member
30: Locking unit
31: Lever
32: Tilt Bolt
33: Fixing nut
34, 35: cam member
40: auxiliary lock structure
41: support block
42: Locking spring member
43:
44: unlocking spring member
46: shock absorbing member
47: Guide member
48: Fixed value
70: energy absorption structure
71: absence of telescopic teeth
73:
75: energy absorbing member
76: cam member
77: Locking spring member
78: Support member
233: compartment slot
83:

Claims (16)

A mounting bracket having a pair of arms facing each other,
A lower housing installed so as to pass between a pair of arms of the mounting bracket,
A steering column including an upper jacket installed through the lower housing to enable telescopic behavior of the lower housing,
A locking unit configured to selectively apply a clamping force to the pair of arms to selectively allow the telescopic behavior of the steering column to be locked or unlocked; and
An energy absorbing structure that operates in conjunction with the locked state or the unlocked state of the lock unit and acts to allow the collapse of the steering column when energy is absorbed when an impact is applied to the steering column in the locked state of the lock unit, Including,
The energy absorbing structure
A telescopic tooth member having a telescopic tooth,
And a telescopic lock having a telescopic lock that is selectively engageable with the telescopic tooth and is selectively engageable with the telescopic lock tooth in the direction of the telescopic movement of the telescopic tooth member through selective engagement of the telescopic lock and the telescopic lock, A locking member operative to selectively block or permit movement, and
Wherein the telescopic tooth member is operative to telescopic with the upper jacket in a state in which movement of the telescopic tooth member in the telescopic movement direction is allowed and the movement of the telescopic tooth member in the telescopic movement direction is blocked And an energy absorbing member that acts to cause energy absorption while the shape is deformed by relative movement of the upper jacket relative to the telescopic tooth member at the time of impact transmission of the upper jacket,
Wherein the energy absorbing member is connected to the body portion and the telescopic tooth member, respectively, and the energy absorbing member is connected to the telescopic tooth member by a shape deformation caused by the relative movement of the upper jacket to the body member and the telescopic tooth member, And a shape deforming portion for generating a deformed shape,
Wherein the telescopic teeth are arranged along the longitudinal direction of the upper jacket,
Wherein the locking member is configured to make a linear movement in a direction toward or away from the telescopic tooth member in response to the switching of the locking unit to a locked or unlocked state
Calpable Steering Column Assembly. The method of claim 1,
And the shape deforming portion comprises a J-shaped strap connected to the body portion. 3. The method of claim 2,
And the shape deforming portion is fastened to the telescopic tooth member by a fastening pin passing through a fastening portion provided at an end portion of the J-shaped strap. 4. The method of claim 3,
Wherein the energy absorbing structure further comprises a guide member secured to the top jacket and guiding the telescopic tooth member during relative movement of the top jacket and the telescopic tooth member in the telescopic direction of movement. 3. The method of claim 2,
And a broken line formed on both sides of the J-shaped strap so as to be able to be broken in a shape deformation process. delete The method of claim 1,
Wherein the lock unit includes a lever capable of pivoting between a locked position and an unlocked position and a tilt bolt configured to rotate with the lever to rotate between a locked position and an unlocked position,
The energy absorbing structure
A cam member configured to push the lock member in a direction away from the telescopic tooth member in response to rotation of the tilt bolt to the unlock position,
A supporting member fastened to the lower housing, and
Further comprising a lock spring member elastically supporting the lock member with respect to the support member in a direction toward the telescopic tooth member. 8. The method of claim 7,
And the support member is resiliently supported by the support spring member fastened to the mounting bracket toward the lock member. The method of claim 1,
Wherein the lock unit includes a lever capable of pivoting between a locked position and an unlocked position and a tilt bolt rotating with the lever and penetrating a pair of arms of the mounting bracket,
Wherein the telescopic tooth member comprises a first portion on which the telescopic teeth are formed and a second portion spaced from the first portion and facing the outer surface of the upper jacket,
Wherein the tilt bolt is installed to pass through a space between the first portion and the second portion. delete delete delete A mounting bracket having a pair of arms facing each other,
A lower housing installed so as to pass between a pair of arms of the mounting bracket,
A steering column including an upper jacket installed through the lower housing to enable telescopic behavior of the lower housing,
A locking unit configured to selectively apply a clamping force to the pair of arms to selectively allow the telescopic behavior of the steering column to be locked or unlocked; and
An energy absorbing structure that operates in conjunction with the locked state or the unlocked state of the lock unit and acts to allow the collapse of the steering column when energy is absorbed when an impact is applied to the steering column in the locked state of the lock unit, Including,
The energy absorbing structure
A telescopic tooth member having a telescopic tooth,
A locking member having a telescopic lock that can be engaged with the telescopic tooth and configured to be movable between a mating and unmating position of the telescopic lock and the telescopic lock in response to a locked or unlocked state of the locking unit,
A cam member configured to move the lock member in a direction in which the engagement of the telescopic lock and the telescopic lock is released in response to switching of the lock unit to the unlocked state,
A lock spring member elastically supporting the lock member in a direction in which the telescopic lock is engaged with the telescopic lock in response to switching of the lock unit to the locked state,
And an energy absorbing member connecting the telescopic tooth member and the upper jacket,
Wherein the telescopic teeth are arranged along the telescopic direction of the upper jacket,
Wherein the locking member is configured to be movable between a mating and disengaging position of the telescopic lock and the telescopic tooth through a linear movement relative to the telescopic tooth member,
Wherein the energy absorbing member functions to move the telescopic tooth member together with the upper jacket in a disengaged state between the telescopic lock tooth and the telescopic tooth and to apply an impact applied to the steering column in the meshed state between the telescopic lock tooth and the telescopic tooth So as to allow the collapse of the steering column while allowing energy absorption through shape deformation
Calpable Steering Column Assembly. The method of claim 13,
Wherein the energy absorbing member is connected to the body portion and the telescopic tooth member, respectively, and the energy absorbing member is connected to the telescopic tooth member by a shape deformation caused by the relative movement of the upper jacket to the body member and the telescopic tooth member, Wherein the deformable portion comprises a shape deforming portion for deforming the deformable portion. The method of claim 13,
Wherein the lock unit includes a lever capable of pivoting between a locked position and an unlocked position and a tilt bolt configured to rotate with the lever to rotate between a locked position and an unlocked position,
And the cam member is fastened to the tilt bolt to rotate together with the tilt bolt. 16. The method of claim 15,
Wherein the energy absorbing structure further comprises a support member supported by a support spring member fastened to the mounting bracket,
And the lock spring member resiliently supports the lock member with respect to the support member.

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